Lesson Overview

Download Report

Transcript Lesson Overview

Lesson Overview
12.1 Identifying the
Substance of Genes
Lesson Overview
Identifying the Substance of Genes
Bacterial Transformation
To truly understand genetics, scientists realized they had to
discover the chemical nature of the gene.
If the molecule that carries genetic information could be
identified, it might be possible to understand how genes
control the inherited characteristics of living things.
Lesson Overview
Identifying the Substance of Genes
Griffith’s Experiments
Griffith isolated two different strains of the same bacterial
species.
Both strains grew very well in culture plates in Griffith’s lab,
but only one of the strains caused pneumonia.
Lesson Overview
Identifying the Substance of Genes
Griffith’s Experiments
When Griffith injected mice with disease-causing bacteria,
the mice developed pneumonia and died.
When he injected mice with harmless bacteria, the mice
stayed healthy.
Lesson Overview
Identifying the Substance of Genes
Griffith’s Experiments
First, Griffith took a culture of the S strain, heated the cells
to kill them, and then injected the heat-killed bacteria into
laboratory mice.
The mice survived, suggesting that the cause of
pneumonia was not a toxin from these disease-causing
bacteria.
Lesson Overview
Identifying the Substance of Genes
Griffith’s Experiments
In Griffith’s next experiment, he mixed the heat-killed, Sstrain bacteria with live, harmless bacteria from the R strain
and injected the mixture into laboratory mice.
The injected mice developed pneumonia, and many died.
Lesson Overview
Identifying the Substance of Genes
Transformation
He called this process transformation, because one type of
bacteria had been changed permanently into another.
Because the ability to cause disease was inherited by the
offspring of the transformed bacteria, Griffith concluded
that the transforming factor had to be a gene.
Lesson Overview
Identifying the Substance of Genes
The Molecular Cause of Transformation
Avery extracted a mixture of various molecules from the
heat-killed bacteria and treated this mixture with enzymes
that destroyed proteins, lipids, carbohydrates, and some
other molecules, including the nucleic acid RNA.
Transformation still occurred.
Lesson Overview
Identifying the Substance of Genes
The Molecular Cause of Transformation
Then they destroyed the DNA in the mixture and
transformation did not occur.
Therefore, DNA was the transforming factor.
By observing bacterial transformation, Avery and other
scientists discovered that the nucleic acid DNA stores and
transmits genetic information from one generation of
bacteria to the next.
Lesson Overview
Identifying the Substance of Genes
Bacteriophages
The kind of virus that infects bacteria is known as a
bacteriophage, which means “bacteria eater.”
A typical bacteriophage is shown.
Lesson Overview
Identifying the Substance of Genes
The Hershey-Chase Experiment
American scientists Alfred Hershey and Martha Chase studied a
bacteriophage that was composed of a DNA core and a protein
coat.
They wanted to determine which part of the virus—the protein coat or
the DNA core—entered the bacterial cell
Hershey and Chase grew viruses in cultures containing
radioactive isotopes of phosphorus-32 (P-32) sulfur-35 (S-35)
Lesson Overview
Identifying the Substance of Genes
The Hershey-Chase Experiment
Nearly all the radioactivity in the bacteria was from phosphorus P32 , the marker found in DNA.
Hershey and Chase concluded that the genetic material of the
bacteriophage was DNA, not protein.
Hershey and Chase’s experiment with bacteriophages confirmed
Avery’s results, convincing many scientists that DNA was the
genetic material found in genes—not just in viruses and bacteria,
but in all living cells.
Lesson Overview
Identifying the Substance of Genes
The Role of DNA
The DNA that makes up genes must be capable of storing,
copying, and transmitting the genetic information in a cell.
Lesson Overview
12.2 The Structure of DNA
Lesson Overview
Identifying the Substance of Genes
Nucleic Acids and Nucleotides
Nucleic acids are long, slightly acidic molecules originally
identified in cell nuclei.
Nucleic acids are made up of nucleotides, linked together to
form long chains.
DNA’s nucleotides are made up of three basic components:
a 5-carbon sugar called deoxyribose, a phosphate group,
and a nitrogenous base.
Lesson Overview
Identifying the Substance of Genes
Nucleic Acids and Nucleotides
The nucleotides in a strand of DNA are joined by covalent
bonds formed between their sugar and phosphate groups.
DNA has four kinds of nitrogenous bases: adenine (A),
guanine (G), cytosine (C), and thymine (T).
Lesson Overview
Identifying the Substance of Genes
Chargaff’s Rules
Erwin Chargaff discovered that
the percentages of adenine [A]
and thymine [T] bases are almost
equal in any sample of DNA. The
same thing is true for the other
two nucleotides, guanine [G] and
cytosine [C].
The observation that [A] = [T] and
[G] = [C] became known as one of
“Chargaff’s rules.”
Lesson Overview
Identifying the Substance of Genes
Franklin’s X-Rays
Rosalind Franklin used Xray diffraction to reveal an
X-shaped pattern that
showed:
- The strands of DNA are
twisted around each
other like the coils of a
spring.
- That there are two
strands in the structure.
- That the nitrogen bases
may be near the center.
Lesson Overview
Identifying the Substance of Genes
The Work of Watson and Crick
The clues in Franklin’s Xray pattern enabled
Watson and Crick to build a
model that explained the
specific structure and
properties of DNA.
They built threedimensional model of DNA
in a double helix, in which
two strands were wound
around each other.
Lesson Overview
Identifying the Substance of Genes
Antiparallel Strands
In the double-helix model, the two
strands of DNA are “antiparallel”—
they run in opposite directions.
This arrangement enables the
nitrogenous bases on both strands to
come into contact at the center of the
molecule.
It also allows each strand of the
double helix to carry a sequence of
nucleotides, arranged almost like
letters in a four-letter alphabet.
Lesson Overview
Identifying the Substance of Genes
Hydrogen Bonding
Watson and Crick discovered that
hydrogen bonds could form
between certain nitrogenous
bases, providing just enough force
to hold the two DNA strands
together.
Hydrogen bonds are relatively
weak chemical forces that allow
the two strands of the helix to
separate.
The ability of the two strands to
separate is critical to DNA’s
functions.
Lesson Overview
Identifying the Substance of Genes
Base Pairing
Watson and Crick realized
that base pairing explained
Chargaff’s rule. It gave a
reason why [A] = [T] and
[G] = [C].
This nearly perfect fit
between A–T and G–C
nucleotides is known as
base pairing, and is
illustrated in the figure.